The Impact on the Ozone Layer of a Potential Fleet of Civil Hypersonic Aircraft

Kinnison, Douglas E.; Brasseur, Guy; Baughcum, Steven L.; Zhang, Jun; Wuebbles, Donald J.

doi:10.1029/2020ef001626

Cited by 13 publications

(20 citation statements)

References 42 publications

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“…The difference between the NOy and H 2 O perturbations is that a much larger fraction of emitted H 2 O is transported southward across the tropics to the SH as well as transported upward to the stratopause into the mesosphere. This is due to the differences in their atmospheric lifetimes, with around 1 year and 3 months lifetime in the upper stratosphere for H 2 O and NOy, respectively (Kinnison et al., 2020). At cruise altitudes from 21 to 23 km, the maximum local H 2 O concentration increase reaches 1.5 ppmv at NH mid‐latitudes and the stratospheric column H 2 O increase by 4.45% in the NH average.…”

Section: Resultsmentioning

confidence: 99%

“…The distribution of ozone is determined by a complex balance between transport and chemical production and destruction (Brasseur, 2020;WMO, 2018). Transport processes influence ozone concentration both by transporting ozone itself and also by the transport of precursors that induce ozone chemical production and transport of other gases that lead to the destruction of ozone (e.g., NOx and H 2 O emitted from aircraft).…”

Section: Ozone Response To the Supersonic Transport Emissionmentioning

confidence: 99%

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Stratospheric Ozone and Climate Forcing Sensitivity to Cruise Altitudes for Fleets of Potential Supersonic Transport Aircraft

et al. 2021

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There is renewed interest in the development of supersonic transport commercial and business aircraft due to a rising demand for more intercontinental air travel as a result of population and economic growth and also a desire for shorter flight times. However, emissions of nitrogen oxides (NOx) and water vapor (H 2 O) from the supersonic aircraft can especially have important environmental effects on ozone and climate

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Section: Resultsmentioning

confidence: 99%

Section: Ozone Response To the Supersonic Transport Emissionmentioning

confidence: 99%

Stratospheric Ozone and Climate Forcing Sensitivity to Cruise Altitudes for Fleets of Potential Supersonic Transport Aircraft

et al. 2021

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“…NO x and H 2 O (after reaction to form hydrogen oxides; HO x ) are known to be important gases in the chemical production and destruction of stratospheric ozone. Both NO x and HO x can be directly involved in catalytic chemical reactions that destroy molecules of stratospheric ozone, both from natural and human-related sources like supersonic aircraft (e.g., Crutzen, 1972;Dessens et al, 2007;Johnston, 1971Johnston, , 1989Kawa et al, 1999;Kinnison & Wuebbles, 1994;Kinnison, Brasseur, Baughcum, et al, 2020;Penner et al, 1999). Emissions of NO x and HO x can interfere with each other's ozone-loss mechanisms and they can also interfere with other ozone-loss mechanisms (e.g., ClO x ).…”

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confidence: 99%

Potential Impacts of Supersonic Aircraft Emissions on Ozone and Resulting Forcing on Climate: An Update on Historical Analysis

et al. 2021

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The overall demands by the public for air travel, the aspiration for more intercontinental travel, and the desire for shorter flight times have all increased in the past few decades. As a result, various companies and organizations around the world have been reconsidering development of supersonic aircraft for the business jet and commercial airline markets (e.g., NASA, Aerion, Spike Aerospace, and Boom Technology). Commercial fleets of supersonic transport (SST) aircraft were first considered in the 1970s (Climate Impact Assessment Program, 1975) and then again in the 1990s (Kawa et al., 1999). The cruise altitudes flown by supersonic aircraft depends on the design and speed of the aircraft with faster aircraft flying at higher altitudes. Supersonic aircraft would fly at higher altitudes than the current fleet of subsonic aircraft, with their emissions primarily being in the stratosphere. With a potential range of cruise altitudes from 13 to 23 km, the majority of emissions from supersonic aircraft would occur in the stratosphere and would have longer atmospheric lifetimes than the emissions occurring from subsonic aircraft that primarily fly in the troposphere. Supersonic aircraft emissions can be

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“…That drew on observations of emissions in the lower stratospheric wake of a Concorde, by the NASA ER‐2 (Fahey et al ., 1995). Grooβ et al ., (1998) and Kinnison et al ., (2020) also modelled these factors.…”

Section: Perspectivementioning

confidence: 99%

“…It is out of scope to review fully the rapid growth in laboratory results, observations and modelling over the half century that has led to the present worldwide efforts and understanding. That has been done by periodic reviews under the aegis of the World Meteorological Organisation, for example (Wahner and Geller, 1994;Lee et al, 2009;WMO, 2018;Kinnison et al, 2020). In the concluding perspective, the lessons of the last half century will be summarised and their implications for the future considered.…”

Section: Introductionmentioning

confidence: 99%

Perspective on aircraft in the stratosphere: 50 years from COMESA through the ozone hole to climate

Tuck

2021

Quart J Royal Meteoro Soc

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A perspective is given on the emissions of aircraft in the stratosphere, on the occasion of the 50th anniversary of the article that initiated concerns about the ability of nitrogen oxides from supersonic airliners to carry chain reactions that would destroy stratospheric ozone, and so subject the biosphere to damaging ultraviolet reaction. The response of the American, British and French governments engaged meteorology, photochemistry and radiative transfer as never before. The UK programme, COMESA (Committee on the Effects of Stratospheric Aircraft), is reviewed, and its influence on subsequent developments through concerns about chlorofluoromethanes, the ozone hole and on to climate change is traced briefly. Perspective is given on the current situation, particularly as regards the effects of aerosol particulate matter, which can include emissions from aircraft, forest fires, volcanoes, sea spray, dust, the biosphere and gas‐to‐particle conversion.

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The Impact on the Ozone Layer of a Potential Fleet of Civil Hypersonic Aircraft

Cited by 13 publications

References 42 publications

Stratospheric Ozone and Climate Forcing Sensitivity to Cruise Altitudes for Fleets of Potential Supersonic Transport Aircraft

Stratospheric Ozone and Climate Forcing Sensitivity to Cruise Altitudes for Fleets of Potential Supersonic Transport Aircraft

Potential Impacts of Supersonic Aircraft Emissions on Ozone and Resulting Forcing on Climate: An Update on Historical Analysis

Perspective on aircraft in the stratosphere: 50 years from COMESA through the ozone hole to climate

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